/* * pthread_mutex_timedlock.c * * Description: * This translation unit implements mutual exclusion (mutex) primitives. * * -------------------------------------------------------------------------- * * Pthreads-win32 - POSIX Threads Library for Win32 * Copyright(C) 1998 John E. Bossom * Copyright(C) 1999,2005 Pthreads-win32 contributors * * Contact Email: rpj@callisto.canberra.edu.au * * The current list of contributors is contained * in the file CONTRIBUTORS included with the source * code distribution. The list can also be seen at the * following World Wide Web location: * http://sources.redhat.com/pthreads-win32/contributors.html * * This library is free software; you can redistribute it and/or * modify it under the terms of the GNU Lesser General Public * License as published by the Free Software Foundation; either * version 2 of the License, or (at your option) any later version. * * This library is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU * Lesser General Public License for more details. * * You should have received a copy of the GNU Lesser General Public * License along with this library in the file COPYING.LIB; * if not, write to the Free Software Foundation, Inc., * 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA */ #include "pthread.h" #include "implement.h" static INLINE int ptw32_timed_eventwait (HANDLE event, const struct timespec *abstime) /* * ------------------------------------------------------ * DESCRIPTION * This function waits on an event until signaled or until * abstime passes. * If abstime has passed when this routine is called then * it returns a result to indicate this. * * If 'abstime' is a NULL pointer then this function will * block until it can successfully decrease the value or * until interrupted by a signal. * * This routine is not a cancelation point. * * RESULTS * 0 successfully signaled, * ETIMEDOUT abstime passed * EINVAL 'event' is not a valid event, * * ------------------------------------------------------ */ { DWORD milliseconds; DWORD status; if (event == NULL) { return EINVAL; } else { if (abstime == NULL) { milliseconds = INFINITE; } else { /* * Calculate timeout as milliseconds from current system time. */ milliseconds = ptw32_relmillisecs (abstime); } status = WaitForSingleObject (event, milliseconds); if (status == WAIT_OBJECT_0) { return 0; } else if (status == WAIT_TIMEOUT) { return ETIMEDOUT; } else { return EINVAL; } } return 0; } /* ptw32_timed_semwait */ int pthread_mutex_timedlock (pthread_mutex_t * mutex, const struct timespec *abstime) { pthread_mutex_t mx; int kind; int result = 0; /* * Let the system deal with invalid pointers. */ /* * We do a quick check to see if we need to do more work * to initialise a static mutex. We check * again inside the guarded section of ptw32_mutex_check_need_init() * to avoid race conditions. */ if (*mutex >= PTHREAD_ERRORCHECK_MUTEX_INITIALIZER) { if ((result = ptw32_mutex_check_need_init (mutex)) != 0) { return (result); } } mx = *mutex; kind = mx->kind; if (kind >= 0) { if (mx->kind == PTHREAD_MUTEX_NORMAL) { if ((PTW32_INTERLOCKED_LONG) PTW32_INTERLOCKED_EXCHANGE_LONG( (PTW32_INTERLOCKED_LONGPTR) &mx->lock_idx, (PTW32_INTERLOCKED_LONG) 1) != 0) { while ((PTW32_INTERLOCKED_LONG) PTW32_INTERLOCKED_EXCHANGE_LONG( (PTW32_INTERLOCKED_LONGPTR) &mx->lock_idx, (PTW32_INTERLOCKED_LONG) -1) != 0) { if (0 != (result = ptw32_timed_eventwait (mx->event, abstime))) { return result; } } } } else { pthread_t self = pthread_self(); if ((PTW32_INTERLOCKED_LONG) PTW32_INTERLOCKED_COMPARE_EXCHANGE_LONG( (PTW32_INTERLOCKED_LONGPTR) &mx->lock_idx, (PTW32_INTERLOCKED_LONG) 1, (PTW32_INTERLOCKED_LONG) 0) == 0) { mx->recursive_count = 1; mx->ownerThread = self; } else { if (pthread_equal (mx->ownerThread, self)) { if (mx->kind == PTHREAD_MUTEX_RECURSIVE) { mx->recursive_count++; } else { return EDEADLK; } } else { while ((PTW32_INTERLOCKED_LONG) PTW32_INTERLOCKED_EXCHANGE_LONG( (PTW32_INTERLOCKED_LONGPTR) &mx->lock_idx, (PTW32_INTERLOCKED_LONG) -1) != 0) { if (0 != (result = ptw32_timed_eventwait (mx->event, abstime))) { return result; } } mx->recursive_count = 1; mx->ownerThread = self; } } } } else { /* * Robust types * All types record the current owner thread. * The mutex is added to a per thread list when ownership is acquired. */ ptw32_robust_state_t* statePtr = &mx->robustNode->stateInconsistent; if ((PTW32_INTERLOCKED_LONG)PTW32_ROBUST_NOTRECOVERABLE == PTW32_INTERLOCKED_EXCHANGE_ADD_LONG( (PTW32_INTERLOCKED_LONGPTR)statePtr, (PTW32_INTERLOCKED_LONG)0)) { result = ENOTRECOVERABLE; } else { pthread_t self = pthread_self(); kind = -kind - 1; /* Convert to non-robust range */ if (PTHREAD_MUTEX_NORMAL == kind) { if ((PTW32_INTERLOCKED_LONG) PTW32_INTERLOCKED_EXCHANGE_LONG( (PTW32_INTERLOCKED_LONGPTR) &mx->lock_idx, (PTW32_INTERLOCKED_LONG) 1) != 0) { while (0 == (result = ptw32_robust_mutex_inherit(mutex)) && (PTW32_INTERLOCKED_LONG) PTW32_INTERLOCKED_EXCHANGE_LONG( (PTW32_INTERLOCKED_LONGPTR) &mx->lock_idx, (PTW32_INTERLOCKED_LONG) -1) != 0) { if (0 != (result = ptw32_timed_eventwait (mx->event, abstime))) { return result; } if ((PTW32_INTERLOCKED_LONG)PTW32_ROBUST_NOTRECOVERABLE == PTW32_INTERLOCKED_EXCHANGE_ADD_LONG( (PTW32_INTERLOCKED_LONGPTR)statePtr, (PTW32_INTERLOCKED_LONG)0)) { /* Unblock the next thread */ SetEvent(mx->event); result = ENOTRECOVERABLE; break; } } if (0 == result || EOWNERDEAD == result) { /* * Add mutex to the per-thread robust mutex currently-held list. * If the thread terminates, all mutexes in this list will be unlocked. */ ptw32_robust_mutex_add(mutex, self); } } } else { pthread_t self = pthread_self(); if (0 == (PTW32_INTERLOCKED_LONG) PTW32_INTERLOCKED_COMPARE_EXCHANGE_LONG( (PTW32_INTERLOCKED_LONGPTR) &mx->lock_idx, (PTW32_INTERLOCKED_LONG) 1, (PTW32_INTERLOCKED_LONG) 0)) { mx->recursive_count = 1; /* * Add mutex to the per-thread robust mutex currently-held list. * If the thread terminates, all mutexes in this list will be unlocked. */ ptw32_robust_mutex_add(mutex, self); } else { if (pthread_equal (mx->ownerThread, self)) { if (PTHREAD_MUTEX_RECURSIVE == kind) { mx->recursive_count++; } else { return EDEADLK; } } else { while (0 == (result = ptw32_robust_mutex_inherit(mutex)) && (PTW32_INTERLOCKED_LONG) PTW32_INTERLOCKED_EXCHANGE_LONG( (PTW32_INTERLOCKED_LONGPTR) &mx->lock_idx, (PTW32_INTERLOCKED_LONG) -1) != 0) { if (0 != (result = ptw32_timed_eventwait (mx->event, abstime))) { return result; } } if ((PTW32_INTERLOCKED_LONG)PTW32_ROBUST_NOTRECOVERABLE == PTW32_INTERLOCKED_EXCHANGE_ADD_LONG( (PTW32_INTERLOCKED_LONGPTR)statePtr, (PTW32_INTERLOCKED_LONG)0)) { /* Unblock the next thread */ SetEvent(mx->event); result = ENOTRECOVERABLE; } else if (0 == result || EOWNERDEAD == result) { mx->recursive_count = 1; /* * Add mutex to the per-thread robust mutex currently-held list. * If the thread terminates, all mutexes in this list will be unlocked. */ ptw32_robust_mutex_add(mutex, self); } } } } } } return result; }